Alkyl Substituent Effects on the Neutral Hydrolysis of l-Acyl - American

1832

J. Org. Chem. 1991,56,1832-1837

7 Hz),5.1 (3 H, m); MS,m/z 315 (M+); HRMS d c d for C2,Hd0 MW 315.2559, found 315.2558 (M+).

Acknowld@ent* We me grateful to Profmaor N. Mmder, Australian National university, for SUPPlflng us with a sample of 5-methoxy-2-tetralone. This work was supported in part by a Grant-in Aid for the Encourage-

ment of Young Scientists, Japan (to R.Y.). Supplementary Material Available: Spectral data for compounds 3,9,17,31,36,49,and 51 and copies of 'H NMR and IR spectra of compounds 25,37,39,41,43, and 47 and 'H NMR spectra of compounds 24 and 46 (15pages). Ordering information is given on any current masthead page.

Alkyl Substituent Effects on the Neutral Hydrolysis of l-Acyl-(3-substituted)-1,2,4-triazoles in Highly Aqueous Reaction Media. The Importance of Solvation Wilfried Blokzijl,la Michael J. Blandamer,lb and Jan B. F. N. Engberts*Ja Department of Organic Chemistry, University of Groningen, Nijenborgh 16,9747 AG Groningen, The Netherlands, and Department of Chemistry, University of Leicester, Leicester LE1 7RH, England Received June 1,1990

The importance of solvation in determining substituenteffeds of alkyl groups has been din a quantitative study of the medium effects of ethanol and 1-propanol on the neutral hydrolysis of 18 l-acyl-(3-substituted)1,2,4triazolea in highly aqueous solutions. The dependence of the pseudo-first-orderrate constants for hydrolysis on the molality of added cosolvent is analyzed in terms of pairwise Gibbs function interaction parameters and individual group contributions to the overall medium effect. It is found that the alkyl substituenteffects depend on the presence of the cosolvent and that this medium dependence is different for different alkyl groups. In addition,the effect is sensitive to the position of the substituent and the overall hydrophobicity of the substrate. Alkyl substituent effects have also been examined for the acid-catalyzed hydrolysis of a series of l-acyl-(3substituted)-l,2,4-triazoles.The solvation dependence of alkyl substituent effects is discussed in terms of changes in hydration of the substrate during the activation process. Noncovalent intermolecular interactions in highly aqueous solutions between chemically inert cosolvents and reacting substrates can seriously affect rate constants of many types of reaction^.^^^ These medium effects are largely governed by the overlap of hydration shells of both substrate and activated complex with the hydration shell of the cosolvent. In the case of cosolvents containing hydrophobic groups, the magnitude of the solvent effect is often dominated by the change in hydrophobicity of the reacting molecule(s) during the activation p r o c e ~ s . ~ Recently we proposed a quantitative treatment for the analysis of medium effects on (idorganic reactions in highly aqueous solvent system^."^ The medium effects were analyzed in terms of pairwise Gibbs energy interaction parameters, which reflect pairwise interactions of both substrate and activated complex with the cosolvent molecule. The theory has been critically tested on a hydrolysis reaction in water in the presence of N-substituted ureas6 and mono- and polyhydric alcohol^.^ Careful application of additivity schemes7 allowed a subdivision of medium effects of cosolvents into group contributions to the overall medium effect. Here, we present a combined quantitative study of substituent effects of alkyl groups*and medium effecta of (1) (a) University of Croningen. (b) University of Leicester. (2) Blandamer, M. J.; Burgese, J.; Engberta, J. B. F. N. Chem. SOC. Rev. 1986,14,237. (3) Engberta, J. B. F. N. Water. A Comprehensive Treatise; Franks, F., Ed.; Plenum: New York, 1979; Vol. 6, Chapter 4. (4) Blandamer, M. J.; Burgess, J.; Engberte, J. B. F. N.; Sanchez, F. Faraday Discuss. Chem. SOC.1988,85,309. (5) Blokzi'l, W.; Jager, J.; Engberte, J. B. F. N.; Blandamer, M. J. J. Am. Chem. doc. 1986,108,6411. (6) Blokzijl, W.; Engberta, J. B. F.N.; Jager, J.; Blandamer, M. J. J. Phys. Chem. 1987,91,6022. (7) Blokzijl, W.; Engberte,J. B. F. N.; Blandamer, M. J. J. Am. Chem. SOC.1990,112, 1197.

ethanol and 1-propanol on the pseudo-first-order rate constants for the pH-independent hydrolysis of 18 1acyl-(&substituted)-l,2,4-triazoles (la-j, 2a,b, h-c,4a,b, 5) in highly aqueous solutions. A large set of substrates was examined in an attempt to subject our quantitative theory to a rigorous test. Furthermore, kinetic medium effects and substituent effects for the water-catalyzed hydrolysis are compared with a relevant set of data for the acid-catalyzed hydrolysis.

Substituent effecta of alkyl groups on rate constants and equilibrium constants in solution have been studied extensively.*15 Although it is now generally agreed that (8) For a previous approach, see: Mooij, H. J.; Engberta, J. B. F. N.; Charton, M. Red. Trav. Chim. Pays-Bas 1988,107, 186. (9) Taft, R. W. Steric Effects in Organic Chemistry; Newman, M. S., Ed.; Wiley: New York, 1956; Chapter 13. (10) Shorter, J. Q. Rev. Chem. SOC.1970,24,433. (11) Shorter, J. Advances in Linear Free Energy Relotionehips; Plenum: New York. 1972: ~- -. KY 98. -(12) LevittlL. S.; Widing, H. F. Rog. Phys. Org. Chem. 1976,12,119. (13) De Tar, D. F. J. Org. Chem. 1980,46, 5166. (14) Charton, M. Prog. Phys. Org. Chem. 1981, 13, 119. I

r

OO22-3263/91/ 1956-1832$02.50/0 0 1991 American Chemical Society

J. Org. Chem., Vol. 56, No.5, 1991 1833

Hydrolysis of 3-Substituted Acyltriazoles Scheme I :

Scheme I1

H

H

H

solvation effects play an important rolet3 it is difficult to identify the contribution of these effects quantitatively. Usually, solvation effects are incorporated in steric substituent c o n ~ t a n t s . ' ~ J " ~The ~ contribution of different inductive effects is controversial. Chartonl' argues that such effects represent artifacts in the analysis of the experimental data, but Hanson16 and otherss23 stress the importance of different inductive, field, and resonance effects. This situation differs from that for gas-phase alkyl substituent effects, which can be analyzed satisfactorily in terms of polarizabfities.m* Our present results indicate that the change in solvation during the activation process is greatly affected by the specific alkyl substituent near the reaction center in the molecule. More remote alkyl substituents also have significant but smaller effects on the solvation change. The finding that the alkyl substituent effects vary substantially when the composition of the aqueous medium is changed emphasizes the important role of solvation in determining substituent effects of alkyl groups. Results and Discussion Theoretical Background. In water-rich media the pH-independent hydrolysis of l-acyl-(3-substituted)1,2,4-triazolesproceeds via a general-base-catalyzedprocess in which water acts both as a nucleophile and a general base.e*2s*26A likely mechanism is shown in Scheme I. (15) Hanson, P. J. Chem. SOC., Perkin Trans. 2 1984,101. (16) Ritchie, C. D.; S er W. F. Prog. Phye. Org. Chem. 1964,2,323. (17) (a) Charton, M. A'm. Chem. SOC.1976,97,3691. (b)Charton, M. J. Am. Chem. SOC. 1977,99,5687. (c) Charton, M. J. Org. Chem. 1979, Perkin Trans. 2 1983,97. 44,903. (d) Charton, M. J. Chem. SOC., (18) Bordwell, F. G.; Fried, H. E. Tetrahedron Lett. 1977, 1121. (19) Adcock, W.; Khor, T. C. J. Org. Chem. 1978,43, 1272. (20) Taft, R. W.; Taagepera, M.; Abboud, J. L. M.; Wolf,J. F.; De Frees, D. J.; Hehre, W. J.; Bartmese, J. E.; McIver, R., Jr!J. Am. Chem. SOC.1978,100,7765. (21) De Frees, D. J.; Taagepera, M.; Levi, B. A.; Pollack, S. K.; Summerhaya, K. D.; Taft, R. W.; Wolfsberg, M.; Hehre, W. H. J. Am. Chem. SOC.1979,101, 5632. (22) Fliszar, S.; Beraldin, M. T. Can. J. Chem. 1979,57, 1772. (23) Kramer, C. R. Z . Phys. Chem. 1986,267, 277. (24) Brauman, J. I.; Blair, L. K.J. Am. Chem. SOC.1970, 92, 5986. (25) (a) Kanijn, W.; Engberta, J. B. F. N. Tetrahedron Lett. 1978, 1787. (b) Kanijn, W. Ph.D. Thesis, Groningen, 1979. Hogg, J. L. J. Org. Chem. 1984, 49, 3161. (26) Copalakriehna, 0.;

Depending on the effectiveness of acid- and base-catalyzed hydrolysis, the rate constants are pH-independent in a particular pH range (ca. 3-6). However, this range is critically determined by the substituents R1and & in the substrate. The acid-catalyzed hydrolysis shows the characteristics of specific-acid catalysis and proceeds via reversible protonation at N-4 in the triazole ring, followed by rate-determining attack of water at the carbonyl moiety (Scheme II).27 For the neutral hydrolysis, the reaction medium consists of 1 kg of water, m, and m, moles of substrate and activated complex, respectively, a small concentration of HC1, and m, moles of a cosolvent C (ethanol or 1-propanol). In all experiments m, is small (ca. mol-kg-'). Product analyses revealed only small amounts of products formed by alcoholysis, which do not complicate the kinetic analyses (see the Experimental Section).' Thus, the medium effects reflect interactions between substrate and activated complex with the added cosolvent molecule. Previously! we derived the following equation, which relates the pseudo-first-order rate constant for water-catalyzed hydrolysis in the binary mixture (k(m,)) with the rate constant in bulk water (k(m,=O)): In [k(m,)/k(m,=O)] = ( ~ / R T ) ( ~ / ~ o ) ~ [ ~ ( -S g(AC-C)lm, -C) - NM,I$m, (1) Here, N is the number of water molecules covalently bound in the activated complex (Le., N = 21, MI is the molar maas of water, and I$ is the practical osmotic coefficient of water. By definition, mo = 1molskg-'. The interactions of substrate S and activated complex AC with cosolvent C are describedeJ by the pairwise Gibbs energy interaction parameters g(S-C) and g(AC-C), respectively. The last term in eq 1 describes the effect of C on the activity of water. Since all solutions me dilute in C, triplet and higher order interactions can be neglected. According to the additivity approach, introduced by Wood,= intermolecular pairwise interaction parameters can be expressed as the sum of specific pairwise Gibbs energy group interactions. Thus, eq 1 can be rewritten as i=k

In [k(m,)/k(m,=O)l = (2/RT)(l/moI2[Cn,(i) G(S-i) i=k

Cn,(i) G(AC-i)]m,

ill

i=l

-

- NM16m, (2)

where G(S-i) and G(AC4) represent the pairwise Gibbs function interaction parameters for interactions of, respectively, substrate and activated complex with n, groups i in the cosolvent molecule. In the dilute solutions we set 4 = 1. The main term in eq 2 represents the difference in the Gibbs function interaction energies of the cosolvent with the substrate and activated complex. It is this term that governs the medium e f f e ~ t . ~The J terms between brackets, multiplied by a scale factor (l/m@, is symbolized by G(C) and can be obtained from a plot of In [k(m,)/k(m,=O)]vs. m,. According to eq 2, medium effects of ethanol and 1propanol can be conveniently expressed in terms of group contributions of the cosolvent OH and CH groups to the overall medium effect, expressed as G(OH) and G(CH). In a next step, substrate and activated complex can be described in terms of constituent groups. Particularly for the activated complex, this is a matter of concern. Two limiting approaches can be considered. In the first, we (27) Fox, J. P.; Jencka, W. P. J. Am. Chem. SOC.1974, I,1436. (28) (a) Savage, J. J.; Wood, R. H. J. Solution Chem. 1976, 10, 733.

(b)Okamoto, B. Y.; Wood, R. H.; Thompson, P. T. J. Chem. SOC., Faraday Trans. I 1978, 74, 1990. (29) Suri, 5. K.; Wood,R. H. J. Solution Chem. 1986,16, 706.

1834 J. Org. Chem., Vol. 56,No.5, 1991

Blokzijl et al.

Table I. Neutral and Acid-Catalyzed Hydrolysis of la-]: Rate Constants, Solvent Deuterium Isotope Effects, and Medium Effects at 25 O C G(EtOH),O G(n-PrOH),’ G(CH),O C(OH),” kH X 102, R1 k X 106, s-l kHm/kwa Jkpmol-2 J-kg.mol-* J.kg.mol-2 J.kg.mol-2 kg.mol%-l la Me 216 3.00 -52 (2) -97 (2) -22 (2) 59 20 29 -158 (3) -28 (3) 37 Ib Et 290 3.13 -103 (2) IC

Id le lfb le lhb li li

n-Pr i-Pr

175 340 41.4 98.0 341 4.27 9.40 203

i-Bu S-BU t-Bu

3.31 3.38 3.49 2.96 3.09 4.15 4.13 2.62

n-Pent 3-Pent Ph a For the neutral hydrolysis. Data from ref 8.

- ln( k(m,)/

Oa3

-107 (1) -155 (2) -133 (2)

-182 (3) -237 (3) -226 (3)

-38 (2) -41 (3) -47 (3)

82 50 102

-185 (1)

-289 (2)

-52 (2)

75

-202 (2) -83 (2)

-324 (5) -172 (3)

-61 (4) -45 (3)

103 142

17 56 5.3 68 2.2 9.4

k (me= 0))

t

P 0.0

0.2

0.3

0.1

0.2

0

~

0

~~

0.5

1.o m,. mol.kg

-1

1.5

Figure 1. Plots of -In [k(m,)/k(m,=O)]vs molality of ethanol for the neutral hydrolysis of l-acyl-l,2,4-triazoles(RICOTr, R2 = H)at 25 “C: 0, R1 = Me; 0 , R1= Et; A, R1 = i-Pr; v, R1 = n-Pr;e, R1= Ph; ., R1 = i-Bu; A, R1= t-Bu; 0 , R1 = 3-Pent.

assume that group interactions of alkyl groups in the substrate and activated complex (described by equivalent methylene groups, Le., CH3 = 1.5 CH2 = 3 CH) remain unchanged during the activation process. Consequently, these pairwise interactions of alkyl groups with groups in the cosolvent cancel, and hence the dependence of rate constants on m, for sets of related substrates (1-5) will be indistinguishable. In the second approach, an attempt is made to take account of differences in the pairwise interactions of an alkyl moiety in the initial and transition states with added cosolvent. This approach js required if the kinetic data reveal that the dependence of In [k(m,)/k(m,=O)]on m, is characteristic of a particular substrate molecule. Kinetic Results. Pseudo-first-order rate constants (k) and solvent deuterium isotope effects (kHg0/kD20)for the neutral hydrolysis as well as second-order rate constants ( k ~ for ) the acid-catalyzed hydrolysis of a series of 1acyl-1,2,4-triazoles(la-j) are given in Table I. The data show that both k and k~ vary considerably upon variation of R1.In Figures 1and 2, In [k(m,)/k(m,=O)]is plotted as a function of the molality of ethanol and 1-propanol, respectively. In all cases linear plots were obtained with

0.1

0

0

0.5

1 .o

-1

1.5

m,, mol. kg

Figure 2. See legend to Figure 1, with cosolvent 1-propanol instead of ethanol.

quite different slopes. The derived values of G(Et0H) and G(n-PrOH) are also recorded in Table I, together with calculated values for G(CH) and G(0H). It is clear that the decrease of the rate Constants upon increasing alcohol concentration is caused by a dominant rate-decreasing contribution of the CH groups. These effects are only partly compensated by a positive contribution of G(0H). For example, for ethanol JSG(CH)I> IG(OH)(. The overall picture is consistent with a loss of hydrophobicity during the activation process. Table I1 compares rate constants for the neutral hydrolysis (k)and for the acid-catalyzed hydrolysis (kH) of a series of l-acyl-(3-sub)-l,2,4triamles.Substantial substituent effects are observed. Medium effects on k are analyzed in terms of plots of In [k(m,)/k(m,=O)]vs mo-

J. Org. Chem., Vol. 56, No.5, 1991 1836

Hydrolysis of 3-Substituted Acyltriazoles

la 20

2b lb 3a

3b 3c lg 4a 4b 1j 5

Table 11. Rate Constants and Medium Effects for the Neutral and Acid-Catalyzed Hydrolysis of l-Acyl-(3-substituted)-l,!2,4-tria~ler Showing the Effect of the 3-Substituent in the Triazole Ring (26 "C) G(EtOH), G(n-PrOH), G(CH), G(OH), k" X loP, R1 Rp k X le,8-l kH*/kw J.kg.mo1-l J.kg.mol-z J.kg.mol-z J-kg.mol4 kg.mo1%-' Me H 216 3.00 -52 (2) -97 (2) -22 (2) 59 20 103 56 -157 (2) -37 (2) t-Bu 59.7 3.06 -83 (2) Me 2.92 c1 692 Me -28 (3) 37 29 H 3.13 -103 (2) -158 (3) 290 Et 67 106 -42 (3) -190 (2) 132 3.19 Me -105 (3) Et 80 167 3.15 t-Bu -272 (4) 82.8 -146 (3) Et -63 (4) 9.5 95 -41 (3) Ph 212 3.24 -159 (3) -110 (3) Et 68 76 -52 (2) -289 (2) 3.09 341 H -185 (1) t-Bu 213 160 -74 (3) 3.04 Me 168 -208 (3) -355 (3) t-Bu -0 241 387 -134 (10) -268 (10) 106 t-Bu -555 (10) t-Bu 9.4 140 -45 (3) -172 (3) 203 2.62 -83 (2) H Ph 2.8 219 -254 (3) 127 2.95 -119 (2) Ph Ph -68 (3)

"Because of the h,h sensit..._y for acid catalysis, and accurate value of kHfl/kw for the neutral hydrolysis is difficult to obtain. Table 111. Spectroscopic Data for l-Acyl-l,2,4-triazoles lacchemical shift,' YC-Of UVL,6 6 R, R, cmnm C 4 C3 C5 1754 218 167.9 152.8 143.1 la Me H 1749 226 173.6 168.2 143.2 20 Me t-Bu 1765 225 2bd Me C1 1752 221 171.4 152.6 143.2 lb Et H 1747 226 171.3 162.6 143.5 3. Et Me 1749 226 173.4 171.7 143.2 3b Et t-Bu 1746 258, 270' 171.7 163.5 143.8 3c Et Ph 1751 217 IC n-Pr H 218 174.5 152.8 143.5 H 1751 Id i-Pr 1750 218 le i-Bu H 1750 219 I f S-BU H 1735 220 175.1 152.1 145.0 11 t-Bu H 1729 227 175.1 162.0 145.4 4a t-Bu Me 229 175.3 172.7 145.0 t-Bu 1726 4b t-Bu 1748 219 l h n-Pent H 1748 219 173.5 152.6 143.2 li 3-Pent H 250 164.2 152.8 145.7 H 1716 1j Ph 1706 273 164.3 163.8 146.3 5 Ph Ph "In CCl,.

water. 'In CDC13. dFrom ref 25. 'From ref 8.

I Wavelength used for monitoring the kinetics of hydrolysis.

c

50

30

lo

t

0 L.*n

0 0.5

1.0

1.5

2.0

2.5

(-134)

0

t (-74) 4

0.2

-

(-21) 0

-C(CH), J. kp.mol-*

70

tf,R,

3.0

E', Figure 3. Plot of C(CH) vs the sum the Rekker hydrophobic fragmental constante (Eti). The substrates are the l-acyl1,2,4-triazolee(RICOTr): R1 = Me (0);R1 = Et (0);R1 = i-Pr (A);R1= n-Pr (e);R1 = P h (VI; R1 = i-Bu (W); R1 = t-Bu (e); R1= 3-Pent (A).

lality of EtOH or n-PrOH, which show perfect linear correlation. Table I1 lists values for C(Et0H) and G(nPrOH) as well as calculated values for C(CH) and G(0H). The alcohol-induced decrease of k is again the result of a dominant contribution of the CH groups in the cosolvent. Interestingly, not only the solvation of R1 but also that of the alkyl group &,which is quite far removed from the

(-10 0

(-41)(-381(-45) (-471 ( - 6 1 ) A @ v m*

(-81)

A

1836 J. Org. Chem., Vol. 56, No.5, 1991

dominant (vide supra). In fact, the contribution of G(CH) correlates well with the hydrophobicity of the substituents R1 and R, in the substrates. Figure 3 shows an almost linear relationship between the sum of Rekker's hydrophobic fragmental constants (cfJs0 of the alkyl substituent R1 (R, = H) and the G(CH) term. There is also a clear trend between the hydrophobicity of Rzand G(CH). In Figure 4 we have constructed a plot using as the horizontal axis the value of Cfi for R1 and as the vertical axis the value of Cfi for R2. The contribution of the CH groups of the cosolvent to the overall medium effect is indicated for the particular substrates. The least hydrophobic subshates are found in the lower left corner of the diagram, whereas the most hydrophobic substrates are in the upper right corner. Between these two regions there is a large increase in the magnitude of G(CH). The diagram also reveals that G(CH) is much more sensitive to changes in hydrophobicity of R1 than to similar changes of Rz. We note that the kinetic medium effect is not correlated with the overall hydrophobicity of the substrate. Presumably, the effects of R, and R2 on G(CH) are not additive. For example, the sensitivity of G(CH) to changes in the hydrophobicity of R1 increases as the substituent R2 is made more hydrophobic. It is evident that changes in G(OH) follow the same trends that are observed for G(CH). However, some important features emerge from a comparison of the medium effects of EtOH and n-PrOH on the k values of isomeric substrates, e.g. le and l g vs IC and Id. It is found that the medium effects are significantly smaller for the substrates in which branching is present at the @-carbonof R, than for the substrates with branching a t the a-carbon (Figures 1 and 2). This effect finds its origin in the larger contribution of G(0H). Furthermore, it is noticeable that the contribution of G(0H) is more important for substrates where R1 is phenyl rather than alkyl. The dependence of the pseudo-first-order rate constants for neutral hydrolysis on R1 and Rz is complex. The substituent effects of R1 do not correlate with known sets of polar or steric alkyl substituent constants.8 Polarisability constants (e.g., P),O do not account for the substituent effects either. Steric effects will play a role since the coordination of the carbonyl carbon atom increases during the activation process. Surprisingly, however, the rate constant increases upon a-branching: Me < Et < i-Pr 5 t-Bu. By contrast, a decrease in rate constant is observed in the series Et > n-Pr > i-Bu > n-Pent and i-Pr > s-Bu > 3-Pent. Thus, steric inhibition is only revealed by branching at the @-carbonatom. Previously, these effects have been correlated by a branching equatione8 It will be noted that for R1= t-Bu there is a significant decrease of the carbonyl stretching vibration and a remarkable downfield shift of the C-5 13CNMR resonance of the triazole ring (Table 111). Following suggestions made by Pinkus et al.31for a comparable effect in methyl alkyl ketones, we submit that out-of-plane twisting of the t-Bu group occurs as a result of steric interference with the triazole moiety. This leads to decreased double-bond character in the carbonyl group, an effect not present for R1 = Me, Et, or i-Pr. Presumably, this effect reduces the hydrolytic reactivity of l g and may explain why Id and lg exhibit similar k values. But, interestingly, the kinetic effect in the series R1 = Me, Et, i-Pr, t-Bu appears to depend on the hydration change involved in the activation (30) Rekker, R.F. The Hydrophobic Fragmental Constant; Elsevier: Amsterdam, 1977. (31) (a) Pinkus, A. G.; Custard, H. C., Jr. J. Phya. Chem. 1970, 74, 1042. (b)Pinkus, A. G.; Lin, E. Y. J . Mol. Struct. 1976,24,9.

Blokzijl et al. process. This is particularly well illustrated for hydrolysis reactions in aqueous solutions containing 5 M i-PrOH. Under these conditions no alcoholysis occurs. Keeping & = H, we find the following k values for neutral hydrolysis: R1 = Me, 112 X lOa s-l;Et, 124 X loa s-l; LPr, 107 X lo4 s-l; t-Bu, 84.3 X s-l. Now the sequence of rate constants is about the reverse of that found in water. In the binary i-PrOH-H20 solution, the hydrophobic hydration shells of the R1 alkyl groups will be largely broken down and, apparently, under these conditions a normal steric effect (including out-of-plane twisting for R1 = t-Bu) for a-branching is observed. The rate constants for the acid-catalyzed hydrolysis ( k ~ ; Tables I and 11)are equally sensitive to substituent effeds of the alkyl group R1. Increasing hydrophobicity of Rl is accompanied by larger kH values (Tables I and 11). In fact, for 4a,b the acid catalysis is so effective that the pH range for the water-catalyzed reaction is very narrow. Just as for the neutral hydrolysis reaction, branching at the acarbon atom has an incremental effect whereas @-branching strongly decreases the rate of acid-catalyzed hydrolysis. Small rate constants are found for substrates with R1 = Ph. Turning now to the effects of the substituents at C-3 in the triazole ring, the first point to note is that these effeds are substantial. By contrast, the solvent deuterium isotope effects and the carbonyl stretching vibrations hardly respond to substituent variation at C-3. An increase in hydrophobicity of the group at C-3 leads to enhanced sensitivity toward acid catalysis as evidenced by the kH values for & = Me, t-Bu. The smallest rate constants are observed for Rz = Ph. We contend that the substituent effects of & on both k and kH are not steric in nature. The substituent R2 also hardly affects the 13C NMR chemical shifts in the triazole ring, apart from that at C-3, as anticipated. It appears that the factor dominating the substituent effect of R2 is an effect on the leaving ability of the triazole moiety. For 3-substituted 1,2,Ctriazoles, the following pK,'s have been found32 10.73 (& = Me), 10.69 (R, = Et), 10.26 (R = H), 9.59 (R = Ph), 8.13 (R = Cl). During the activation process for the neutral hydrolysis, there will be an increase of the negative charge at N-1, and this may explain the finding that log k exhibits an inverse correlation with pKa. For the acid-catalyzed hydrolysis, there is a correlation between log kH and the pKa of the corresponding 3-substituted triazolium ion: 3.28 (R, = Me), 3.20 (& = Et), 2.27 (R = H), 2.05 (& = Ph).3, Thus, it seems that the simplest way to explain the alkyl substituent effect of R2 is in terms of a rate-decreasing effect on the leaving ability of the triazole ring (neutral hydrolysis) and a rate-enhancing effect as a result of an increase in basicity (acid-catalyzed hydrolysis). The exact molecular basis of these effects yet remains obscure.

Conclusion The present study shows that a quantitative treatment of medium effects on simple hydrolytic reactions in highly aqueous reaction media in terms of pairwise Gibbs energy interaction parameters and group contributions constitutes a highly useful procedure to understand substituent effects and reaction mechanisms in water and water-rich binary solvents. The data presented here show that alkyl substituent effects on the neutral and acid-catalyzed hydrolysis of a large series of l-acyl-(3-substituted)-1,2,4triazoles can be analyzed in terms of steric and solvation effects. But the most important conclusion is that the (32) Krager, C. F.; Freiberg, W. Z. Chem. 1966,6, 381.

Hydrolysis of 3-Substituted Acyltriazoles

steric alkyl substituent effects themselves are strongly modulated by solvation changes during the activation process. In highly aqueous solutions the rate constants increase with increasing hydrophobicity of the alkyl substituents due to solvation effects, but the effect depends critically o n the presence of an alcoholic cosolvent.s3 In water, alkyl substituent effects reflect t h e loss of hydrophobic surface of the substrate during t h e activation process. This reduction of hydrophobic hydration is larger if more hydrophobic substituents are present as indicated b y the increased medium effect of relatively hydrophobic cosolvents. As anticipated, alkyl groups near the reaction center exert a'more pronounced solvation effect than more remote alkyl groups. The overall substituent effects of large alkyl groups that decrease the rate constant for hydrolysis because of steric hindrance are, in fact, reduced because of a counteracting rateincreasing contribution due to the solvation effect as t h e alkyl moiety becomes more hydrophobic. This situation implies that any set of steric alkyl substituent constants, derived from kinetic data for reactions in water or highly aqueous reaction media, will contain a substantial contribution of solvation effects. Experimental Section Materials. Ethanol (p.a.1 and l-propanol (p.a.1 were supplied by Merck and were used without further purification. Demineralized water was distilled twice in an all-quartz distillation unit. All solutions were made up by weight and contained 4 X mol-dm" HCl (to suppress catalysis by hydroxide ions) for the measurement of rate constants for neutral hydrolysis and appropriate concentrations of HCl for the measurement of rate constants of acid-catalyzedhydrolysis. Solvent deuterium isotope effects were measured with D20 solutions that contained 4 X 10" mol&+ DCl. Generally,the pH range in which the reaction rate constant is independent of the actual pH is very small for compounds that undergo very effective acid catalysis. Therefore, measurements were performed between pH 4 and 4.5. The 1acyl-(3-substituted)-1,2,4-triazoles la-j, 2b, and 5 have been reported previously.%%The new substrates (vide infra) were prepared from the corresponding acyl chloride and 3-substituted 1,2,4-triazole according to a standard procedure?*% Solid 1acyl-1,2,4-triazoles were recrystalized twice from n-hexane, and the liquid substrates were distilled in vacuo. The 3-tert-butyl3-methyl-1,2,4-tria~ole,~ and 3-phenyl-1,2,41,2,4-triazole~,~ triazolew were prepared with use of standard procedures. NMR spectra were recorded on a Varian VXR-300instrument with TMS as an internal standard. l-Methanoyl-3-tert-butyl-1,2,4-triazole (2a): ibp 100-101 OC (1mmHg); 'H NMR (CDC13)6 1.34 (s,9 H), 2.64 (s,3 H), 8.75 (8, 1H); 'W NMR (CDCl3) 6 21.99 (p), 28.78 (p), 32.82 (q), 143.15 (91, 173.63 (9). l-Ethanoyl-3-methyl-1,2,4-triazole (3a): mp 71-73 OC; 'H NMR (CDCl3) d 1.25 (t,3 H), 2.38 (8, 3 H), 3.10 (4, 2 H), 8.81 (8, 1H); 'W NMR (CDCl3) 6 7.66 (p), 13.73 (p), 28.01 (s),143.46 (t), 162.58 (q), 171.29 (9). l-Ethanoyl-3-tert -butyl-1,2,4-triazole (3b): bp 75-77 O C ; 'H NMR (CDCl3) 6 1.22 (t, 3 H), 1.32 ( ~ , H), 9 3.05 (4, 2 H), 8.75 (8, 1 H); "C NMR (CDC13) 6 7.65 (p), 27.96 (s),28.73 (p), 32.81 (33) Compare: Hoefnagel, A. J.; Wepeter, B. M. J. Chem. Soc.,Perkin Trans. 2 1989,977. (34)Knope, H. J.; Lunkenheimer,W.; Fedtke, C. Ger. Offen. DE 3,32, 271;Chem. A k t r . 1986,102,P216901 S (Bayer AG). (35) Jones, R. G.; Ainsworth, C . J. Am. Chem. SOC.1955, 77, 1538.

J. Org. Chem., Vol. 56, No.5, 1991 1837 (q), 143.23 (t),171.67 (q), 173.41 (4).

l-Ethanoyl-3-phenyl-1,2,4-triazole (3c): mp 60-62 OC; 'H NMR (CDC13)6 1.33 (8, 3 H), 3.18 (q, 2 H), 7.45 (m, 5 H), 8.92 (8, 1 H); 13C NMR (CDCl3) 6 7.77 (p), 28.11 (s),126.79, 128.56, 129.37, 130.2, 143.84 (t),163.46 (q), 171.70 (9). 1-(2-Methylpropionyl)-3-methyl-l,2,4-triazole(4a): bp 50-51 "C (0.7 mmHg); 'H NMR (CDC13)6 1.38 (s,9 H), 2.34 (8, 3 H), 8.72 (s, 1H); 13CNMR (CDCl3) 6 13.83 (p), 26.68 (p), 41.08 (q), 145.37 (t), 161.99 (q), 175.14 (q). 1-(2-Methylpropionyl)-3-tert-butyl-l,2,4-triazole (4b): bp 180-182 OC (8mmHg); 'H NMR (CDC13)6 1.30 (s,9 H), 1.40 (a, 9 H), 8.70 (8, 1H); 13CNMR (CDC13)6 26.71 (p), 28.75 (p), 32.70 (q), 41.06 (q), 145.04 (t), 172.66 (q), 175.29 (9). Product Analysis. The reaction products of the solvolysis of compounds la,b,g,j, 4a, and 5 were analyzed quantitatively. Hereto, reactions were performed in the presence of 0.5,1.0, and 1.5 molekg-' ethanol and l-propanol, respectively. The substrate concentration in these experiments was always about 5 X m~l-dm-~, the HCl concentration was 4 X 10" m ~ l d m - and ~ , the pH was checked before and after the reactions. After completion of the reaction, the products were analyzed by gas chromatography (Hewlett-Packard 5890 instrument, equipped with a 15-m widebore HP1 fused silica column) and, if necessary, by GC-MS (Ribermag R-10-1Oc) with the authentic triezoles, acids, and eaters. The relative amounts of alcoholysis were determined by calibration. In every case, traces of ethyl and propyl ester could be determined. Independent experiments showed that the esters were not formed by esterification of the acid, formed after hydrolysis. The yield of the eater depended linearly on the molality of alcohol present. Although slight differences were found between the amounts of ester for the different substrates studied, the amount of ethyl ester formed at 1.5 mol-kg-' ethanol never exceeded 3 f 1% and the amount of propyl ester was even smaller, that is 2 f 1%. Kinetic analysis showed that this small amount of alcoholysis does not hamper our quantitative analysis of medium effects. Kinetic Measurements. The pseudefmt-order rate constants were determined by following the change of absorbance at appropriate wavelengths; see Table III. About 3 p L of a concentrated mol-dm") was added to stock solution in acetonitrile (5 x the reaction medium (2.5 cm3) in a quartz UV cell (1cm) that was placed in a thermostated cell compartment of a spectrophotometer (Perkin-Elmer X5, equipped with a data station or a Perkin-Elmer X2 connected to a standard PC). The reactions were followed for about 10 half-lives, and excellent first-order kinetics was observed in all cases. For compound 4b, some solubility problems occurred and some delay time was applied after injection of the probe solution before data points were collected. For every measurement about 1W150 data points were used. For the fast reactions, the PE A2 was used and rate constants were calculated by a commercially available fitting program. Slower reactions were measured on both the X5 and the X2 with an end value approach as well as a fitting program. Rate constants at each molality of cosolvent were measured at least three times and were reproducible to within 1%. For the calculations of the value of G(C) from data, obtained at at least six molalities, a least-squares procedure was used. The rate constants for the acid-catalyzed hydrolysis were calculated from pseudo-first-order rate constants obtained at six different pH values, by a leastsquares analysis.

Acknowledgment. We t h a n k the University of Leigrant to M'J'B' cester for a Supplementary Material Available: 'H and 13C NMR spectra of the novel compounds 2a, 3a-c, and 4a,b (13 pages). Ordering information is given on any current masthead page.